NCP623MN-50R2G

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DROPOUT (mV)

−40

250

TEMPERATURE (°C)I

O

(mA)

Figure 14. Dropout Voltage versus I

out

Figure 15. Dropout Voltage versus Temperature

−20 0 20

150

100

0

100

200

50

40 60 80

DROPOUT (mV)

10 60

250

200

150

100

0

150

50

100

TYPICAL PERFORMANCE CHARACTERISTICS

85°C

25°C

−40°C

150 mA

100 mA

60 mA

10 mA

−40

2.1

0

7.0

AMBIENT TEMPERATURE (°C)

GROUND CURRENT (mA)

Figure 16. Ground Current versus Output Current

OUTPUT CURRENT (mA)

Figure 17. Ground Current versus Ambient

Temperature

V

in

= 3.8 V

V

out

= 2.8 V

C

O

= 1.0 mF

T

amb

= 25°C

GROUND CURRENT (mA)

20 40 100 −20 0 20 40 60 80

1.0

0

2.05

2.0

1.95

1.9

1.8

1.85

60 80 120 140 200160 180

2.0

3.0

4.0

5.0

6.0

V

in

= 3.8 V

V

out

= 2.8 V

C

O

= 1.0 mF

I

out

= 60 mA

Figure 18. Quiescent Current versus Temperature

−40

200

TEMPERATURE (°C)

−20

110

100

02040

60

10080

120

130

140

150

160

170

180

190

QUIESCENT CURRENT ON MODE (mA)

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11

BYPASS CAPACITOR (nF)

Figure 19. Output Voltage Settling Time versus

Bypass Capacitor

Figure 20. Output Voltage Settling Shape

C

bypass

= 10 nF

V

in

= 3.8 V

V

out

= 2.8 V

C

O

= 1.0 mF

I

out

= 60 mA

T

amb

= 25°C

V

in

= 3.8 V

V

out

= 2.8 V

C

out

= 1.0 mF

I

out

= 50 mA

T

amb

= 25°C

Figure 21. Output Voltage Settling Shape

C

bypass

= 3.3 nF

Figure 22. Output Voltage Settling Shape without

Bypass Capacitor

0

1200

1.0 2.0 3.0 4.0 6.0 10

1000

800

600

400

0

200

5.0 7.0 9.08.0

200 ms/div

500 mV/div

C

byp

= 10 nF

V

in

= 3.8 V

V

out

= 2.8 V

C

out

= 1.0 mF

I

out

= 50 mA

T

amb

= 25°C

100 ms/div

500 mV/div

C

byp

= 3.3 nF

V

in

= 3.8 V

V

out

= 2.8 V

C

out

= 1.0 mF

I

out

= 50 mA

T

amb

= 25°C

10 ms/div

500 mV/div

C

byp

= 0 nF

SETTLINE TIME (mA)

TYPICAL PERFORMANCE CHARACTERISTICS

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TYPICAL PERFORMANCE CHARACTERISTICS

Figure 23. Line Transient Response

dV

in

= 3.2 V

Y2

Y1

V

in

= 3.8 to 7.0 V

Y1 = 1.0 mV/div

Y2 = 1.0 V/div

X = 1.0 ms

I

out

= 60 mA

T

amb

= 25°C

Y1: OUTPUT CURRENT, Y2: OUTPUT VOLTAGEY1: OUTPUT CURRENT, Y2: OUTPUT VOLTAGE

Figure 24. I

out

= 3.0 mA to 150 mA

Figure 25. I

Slope

= 100 mA/ms (Large Scale)

I

out

= 3.0 mA to 150 mA

V

in

= 3.8 V

Y1 = 100 mV/div

Y2 = 20 mV/div

X = 200 ms/div

T

amb

= 25°C

Y2

Y1

V

in

= 3.8 V

Y1 = 50 mA/div

Y2 = 20 mV/div

X = 20 ms

T

amb

= 25°C

Y2

Y1

Y1: OUTPUT CURRENT, Y2: OUTPUT VOLTAGEY1: OUTPUT CURRENT, Y2: OUTPUT VOLTAGE

Figure 26. I

Slope

= 6.0 mA/ms (Large Scale)

I

out

= 3.0 mA to 150 mA

Figure 27. I

Slope

= 2.0 mA/ms (Large Scale)

I

out

= 3.0 mA to 150 mA

V

in

= 3.8 V

Y1 = 50 mA/div

Y2 = 20 mV/div

X = 100 ms

T

amb

= 25°C

Y2

Y1

V

in

= 3.8 V

Y1 = 50 mA/div

Y2 = 20 mV/div

X = 200 ms

T

amb

= 25°C

Y2

Y1

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NCP623MN-50R2G

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Manufacturer:

ON Semiconductor

Description:

LDO Voltage Regulators 150 LDO

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